DE102008031959B4 - Method and device for furnaces for optimizing a furnace travel - Google Patents

Abstract

The invention relates to a method and a device for extending the furnace campaign by avoiding cracks in the stones and the chipping of parts of the stones, and reducing joints in melting furnaces. Said aim is achieved by a measurement of the forces/pressures/moments of the furnace stones occurring against each other, or of the furnace stones against the bracing and defined necessary counter forces, such that the forces between the stones, or between the bracings and the stones are below the maximum permissible compression (pressure force) of the stones, and the forces required for avoiding joints between the stones are ensured. Said process occurs automatically as a form of control by determining the force of sensors, analysis of processors and data, and activation of actuators for generating counter forces.

Description

The invention relates to a method and a device for extending the furnace travel, by avoiding cracks in the stones and chipping off parts of the stones in a smelting furnace.

This is achieved by the maximum allowable forces, pressures and moments of the stones used in the furnace against each other and / or between the stones of the furnace and the anchorage, below, by measuring the forces / pressures / moments of the stones with each other and / or Stones against the pressure elements of the anchoring, the evaluation of the data and the automatic subsidence or tightening of the pressure elements, especially when annealing the furnace, and during the Abbottempern.

Such ovens are among others from the publications US 2004/0069192 A1 . JP 63270322 A and US 2029052 A known.

Previous systems in the field of glass melting technology are kiln systems, which are constructed from selected refractory materials. In order to hold the individual components in their fixed position and to absorb the considerable forces in some areas, extensive steel structures are necessary, which are summarized under the term anchors.

The basis of all anchorages in glass melting tanks is the grate resting on pillars and longitudinal beams made up of wide-flange girders. The tank basin, which is mainly constructed of palisade stones, must be tempered as far as possible and fixed in such a way that it is not pushed apart by the hydrostatic pressure of the glass melt. Mostly round rods are used, which are attached to the support posts and supported by angle and U-iron the tub stones. The setting can be made via the round rods designed as screw spindles.

In addition to the pillars with the support grid, the anchoring of the trough vault is one of the most important anchorages of every furnace. The thermal expansion during annealing must be controlled safely, and the vault can only pass through the oven travel safely if it is crack-free and has no joints. In the vault, it is better to accept a pressure than a gap that is not closed.

A significant improvement in the vault anchoring brought the use of disc spring packages between anchorage and pendulum support. The springs prevent the vault forces from increasing inappropriately, even if the anchor bolts are not lowered in time.

A prerequisite for a successful tempering is the knowledge of the thermal expansion of the refractory materials used, taking into account the changes in length during the crystal transformation.

It is important to distinguish between the load-bearing anchors with the pressure elements, which are permanently loaded statically, such as support of the vault, carrying individual furnace components and the holding anchors with the pressure elements. The retaining anchors have only the task of counteracting the thermal expansion of the masonry during annealing, cooling and reheating, so that the stability and gas tightness of the masonry is guaranteed.

Task:

The release, or the tightening, of the pressure elements is based on experience and tables. This can cause joints or impermissibly high forces / pressures / moments on the stones, which form cracks in the stones or flake off parts of the stones, which drastically reduces the service life (furnace travel) of the glass melting furnace.

The invention is therefore an object of the invention to provide a method with control and a device with which the furnace travel is extended by glass furnaces by impermissibly high forces / pressures / moments are suppressed on the stones.

The object of the invention is achieved by the characterizing part of claims 1 to 8.

The respective embodiments are specified in the subclaims.

The advantages achieved by the invention are essentially to be seen in the fact that the forces / pressures / moments occurring on the stones always remain below the maximum permissible values of the stones. Cracks in the stones and the resulting chipping of parts of the stones by inadmissibly high forces / pressures / moments on the stones is hereby safely prevented.

Untreated stones have a higher resistance to chemical reactions and better withstand the mechanical abrasion of the glass. The kiln journey is thus significantly extended, while maintaining the avoidance of joints between the stones.

Description:

The invention, as characterized in claims 1 to 8 and in the dependent claims, solves the problem of the occurrence of cracks in the stones ( 4 to 8th ) or the chipping off of parts of the stones ( 4 to 8th ), as well as joints between the stones ( 4 to 8th ) of the melting furnace, in particular to prevent during tempering or Abtempern and thereby allow a longer oven travel by the forces / pressures / moments between the stones ( 4 to 8th ) of the melting furnace and / or between the stones ( 4 to 8th ) of the melting furnace and the pressure elements ( 12a . 13 ) of anchoring ( 1 to 3 ), an evaluation of the measured values takes place and the pressure elements ( 12a . 13 ) are automatically attracted or decreased depending on the evaluation of the values.

1 shows the method of claim 1 and the apparatus according to claim 5 of a preferred embodiment designed so that the controlled system and the entire device to existing furnace designs, for. B. for the tempering, can be placed.

1 shows a section of a section through the oven room; the hydrostatic pressure coming from the molten glass ( 9 ) on the side wall of the melting tank ( 5 ) over the partition ( 11 ) with the support units ( 11a ) on the pressure element ( 13 ), in this case as a motion screw ( 13 ), is transmitted via the guide thread of the motion screw ( 13a ) on the anchoring of the page ( 2 ) transfer.

By means of a force / pressure sensor ( 14 ), the / on the motion screw ( 13 ) measured force / pressure and the data obtained via the control line of the sensor ( 23 ) to the data evaluation and control unit ( 24 ) and the results of the evaluation as control pulses, via the control line of the actuators ( 24 ) to the motorized actuators ( 15 ), thereby causing an axial displacement of the movement screw ( 13 ) to perform the screw axis, whereby the / on the movement screw ( 13 ) force and pressure changes and thereby compliance with the limit values of material characteristics of the stones ( 4 to 8th ) is safely ensured, so that the formation of cracks in the stones ( 4 to 8th ) and / or the chipping off of parts of the stones ( 4 to 8th ) of the melting furnace due to an inadmissibly high pressure of the stones ( 4 to 8th ) is prevented and joints, by observing minimum values, be prevented. Another method of a preferred embodiment according to 2 may be designed so that the controlled system and the entire device remain permanently as elements during the entire furnace travel and constitute components of the furnace.

2 shows a partial section through the oven room; the hydrostatic pressure coming from the molten glass ( 9 ) on the side wall of the melting tank ( 5 ) over the partition ( 11 ) with the support units ( 11a ) on the pressure elements ( 12a . 13 ), the piston rod ( 12a ) of the hydraulic cylinder ( 12 ), which also by appropriate, familiar to the expert alternatives, eg. As pneumatic or other hydrostatic pressure elements, with the anchoring of the side ( 2 ) is applied, generated in the hydraulic cylinder ( 12 ) a pressure via the hydraulic line A ( 16 ) is transmitted.

By means of the pressure sensor A ( 18 ) on the hydraulic cylinder ( 12 ) and determines the data via the control line of the sensor system ( 23 ) to the data evaluation and control unit ( 24 ), the results of the evaluation as control pulses via the control line of the actuators ( 24 ) to the pressure control valves-A ( 17 ) passed through the hydraulic line A ( 16 ) of the hydraulic adjustable pressure generation with switching logic ( 22 ) is supplied with a correspondingly pressurized hydraulic fluid, thereby an axial displacement of the piston rod ( 12a ) of the hydraulic cylinder ( 12 ), whereby the on the hydraulic cylinder ( 12 ) and thus the compliance with the limit values of material characteristics of the stones ( 4 to 8th ), is guaranteed by the controlled system safely. The vault ( 8th ), which is designed to be cantilevered, by the vault ( 7 ) with the intermediate holder ( 7a ) on the motion screw ( 13 ), the description of the execution was explained earlier in the text, the weight of the vault ( 8th ) and the associated surface pressure on the burner block ( 6 ) can be limited by the method and the device and adjusted seamlessly. In addition to a selection of specific anchorages ( 1 to 3 ) or the equipment of all anchorages ( 1 to 3 ) for automatic, controlled release or tightening of the pressure elements ( 12a . 13 ), there is the possibility of a time limit, for. B. for tempering, as in 1 shown as well as the permanent use of the method and apparatus as a part of the furnace.

The inclusion of other measurable factors, such as temperature in, on and around the furnace or stones ( 4 to 8th ) chemical composition of the exhaust gases and / or the melt, as well as other data from the pressure transmission medium such. As hydraulic fluid, compressed air, the materials used and the environment in the evaluation for controlling the pressure elements ( 12a . 13 ), offers further possibilities for a more precise regulation and is also in an emergency, eg. B. by automatically introducing the Abtempervorganges, without damaging the furnace components, can be used or can indicate premature wear of components or exceeding limit values by data anomalies.

Of course, it is clear to those skilled in the art that the data can be determined in analog or digital form, as well as the evaluation of the data and the forwarding of the result events, the interconnection can be done as a network, in sections or in individual mode. It is known to the person skilled in the art of hydraulics / pneumatics that not all hydraulic / pneumatic cylinders have to be driven by a pressure generating element, but can be combined in groups, with corresponding ballast elements, operated. It may even be useful in individual cases, each pressure element ( 12a ) to assign a separate pressure generating element.

The application of tensile and compressive forces of the pressure elements ( 12a . 13 ) opposite the stones ( 4 to 8th ) allows a translatory movement in a certain direction and back, whereby individual stones ( 4 to 8th ) or sections to barriers, forcing a glass flow in the glass bath ( 9 ) or vortex and pressure control possibilities in the upper furnace ( 10 ) or regulation of the exhaust gas pressure, by changing the passage cross-section, the exhaust gases from the furnace to allow.

In 2 is with the hydraulic line B ( 19 ), the pressure regulating valve B ( 20 ) and the pressure sensor B ( 21 whose function is described earlier in the text for the hydraulic line A ( 16 ), and advantageous with a distance measurement by the encoder ( 12b ), which in the case of a motion screw ( 13 ) may also be a rotary encoder, the possibility of a regulated translational movement of the pressure element ( 12a . 13 ), here the piston rod ( 12a ), whereby, by means of a compound known to the person skilled in the art, 4 to 8th ) and the pressure elements ( 12a . 13 ), a translational displacement of the stones ( 4 to 8th ) by the adjustment of the pressure elements ( 12a . 13 ).

The claims are not limited exclusively to the glass melting, also other areas of glass production, such as the refining and homogenization, as well as the areas of metal melting and mineral melt are subject to the claims.

LIST OF REFERENCE NUMBERS

1

Anchoring the soil

2

Anchoring the page

3

Anchoring the ceiling

4

Bottom of the melting tank

5

Side wall of the melting tank

6

Brennerstein

7

Vaulted abutment stone

7a

intermediate holder

8th

vault

9

glass bath

10

top furnace

11

partition

11a

support unit

12

hydraulic cylinders

12a

Piston rod of the hydraulic cylinder

12b

Encoder / distance measuring unit

13

leading screw

13a

Guide thread of the motion screw

13b

Head of the motion screw; for manual adjustment

14

Force / pressure sensors

15

Motor-driven actuator

16

Hydraulic line-A

17

Pressure regulator-A

18

A pressure sensor

19

Hydraulic line-B

20

Pressure control valve B

21

Pressure sensor B

22

Hydraulic pressure generation with switching logic

23

Control line of the sensors

24

Data evaluation and control unit

25

Control line of the actuators

Claims (8)

Method for melting furnaces, in that the adjustable pressure elements ( 12a . 13 ), between the supporting anchors ( 1 to 3 ) and the stones ( 4 to 8th ) of the melting furnace and / or the holding fixtures ( 1 to 3 ) and the stones ( 4 to 8th ) of the melting furnace, are attracted and released, characterized in that a translatory displacement in a certain direction and back can take place, wherein the pressure elements ( 12a . 13 ), after sensory identification ( 14 . 18 . 21 ) of the individually locally prevailing forces / pressures and the evaluation of the forces / pressures in the data evaluation and control unit ( 24 ) for adjusting the forces / pressures on the individual stones ( 4 to 8th ) or sections of stones ( 4 to 8th ) is automatically controlled and thus on the individual stones ( 4 to 8th ) or sections of stones ( 4 to 8th ) a compressive and tensile force can be exercised automatically regulated. Method according to claim 1, characterized in that the forces / pressures / moments between the stones ( 4 to 8th ) are determined by sensors. A method according to claim 1, characterized in that the values are determined indirectly, by means of distance or gap measurement. Method according to at least one of the preceding claims, characterized in that further values from measurable factors are included in the evaluation in order to enable a more accurate control. Apparatus for melting furnaces, in which the adjustable pressure elements ( 12a . 13 ), between the supporting anchors ( 1 to 3 ) and the stones ( 4 to 8th ) of the melting furnace and / or the holding fixtures ( 1 to 3 ) and the stones ( 4 to 8th ) of the melting furnace, by drives ( 12 . 15 ) are tightened and released, characterized in that the pressure elements ( 12a . 13 ) by means of corresponding drives ( 12 . 15 ) automatically controlled by the data evaluation and control unit ( 24 ), thus including sensors ( 14 . 18 . 21 ) measured factors, the individually locally prevailing forces / pressures on the individual stones ( 4 to 8th ) or sections of stones ( 4 to 8th ) by means of the pressure elements ( 12a . 13 ) a compressive and tensile force is automatically regulated applied. Device according to claim 5, characterized in that the drives ( 12 ), are hydraulic elements. Device according to claim 5, characterized in that the drives ( 12 ), pneumatic cylinder elements are. Apparatus according to claim 5, characterized in that the pressure elements ( 13 ), by servomotors ( 15 ) are moved.

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